Using a zone of constant temperature and denaturant concentration in capillary electrophoresis, we have devised a simple, rapid, and reproducible system for separating mutant from wild type DNA sequences with high resolution. Important to the success of this method, which we call Constant Denaturant Capillary Electrophoresis (CDCE), has been the use of linear polyacrylamide at viscosity levels that permit facile replacement of the matrix after each run. For a typical 100 bp fragment, point mutation-containing heteroduplexes are separated from wild type homoduplexes in less than 30 minutes. Using laser-induced fluorescence to detect fluorescent-tagged DNA, the system has an absolute limit of detection of 3 x 10(4) molecules with a linear dynamic range of six orders of magnitude. The relative limit of detection at present is 3 x 10(-4), i.e. 10(5) mutant sequences are recognized among 3 x 10(8) wild type sequences. The new approach should be applicable to the identification of low frequency mutations, to mutational spectrometry and to genetic screening of pooled samples for detection of rare variants.
We have found that human organs such as colon, lung, and muscle, as well as their derived tumors, share nearly all mitochondrial hotspot point mutations. Seventeen hotspots, primarily G --> A and A --> G transitions, have been identified in the mitochondrial sequence of base pairs 10,030-10,130. Mutant fractions increase with the number of cell generations in a human B cell line, TK6, indicating that they are heritable changes. The mitochondrial point mutation rate appears to be more than two orders of magnitude higher than the nuclear point mutation rate in TK6 cells and in human tissues. The similarity of the hotspot sets in vivo and in vitro leads us to conclude that human mitochondrial point mutations in the sequence studied are primarily spontaneous in origin and arise either from DNA replication error or reactions of DNA with endogenous metabolites. The predominance of transition mutations and the high number of hotspots in this short sequence resembles spectra produced by DNA polymerases in vitro.
This manuscript reports on five cases of spontaneous myelogenous leukemia, similar to human disease, occurring within highly inbred, histocompatible sublines of Massachusetts General Hospital (MGH) MHC-defined miniature swine. In cases where a neoplasm was suspected based on clinical observations, samples were obtained for complete blood count, peripheral blood smear, and flow cytometric analysis. Animals confirmed to have neoplasms were euthanized and underwent necropsy. Histological samples were obtained from abnormal tissues and suspect lesions. The phenotype of the malignancies was assessed by flow cytometric analysis of processed peripheral blood mononuclear cells and affected tissues. Five cases of spontaneous myeloid leukemia were identified in adult animals older than 30 months of age. All animals presented with symptoms of weight loss, lethargy, and marked leukocytosis. At autopsy, all animals had systemic disease involvement and presented with severe hepatosplenomegaly. Three of the five myelogenous leukemias have successfully been expanded in vitro. The clustered incidence of disease in this closed herd suggests that genetic factors may be contributing to disease development. Myelogenous leukemia cell lines established from inbred sublines of MGH MHC-defined miniature swine have the potential to be utilized as a model to evaluate therapies of human leukemia.
We used high fidelity PCR and constant denaturant capillary electrophoresis (CDCE) [Khrapko et al. (1994) Nucleic Acids Res., 22, 364-369] to separate wild type and different mutant N-ras exon 1 and 2 sequences. The set of plasmids containing N-ras cDNA, wild type or mutant sequences representing all transforming amino acid-substituting single base pair changes in codons 12, 13 (exon 1) and 61 (exon 2), were amplified using Pfu polymerase in a limited cycle polymerase chain reaction. One of the primers used for the amplification of each exon included a 40 nucleotide GC rich sequence that created high and low melting domains. The amplified fragments 151 bp (exon 1) and 150 bp (exon 2) were run on the CDCE with the 'denaturant zone' temperature of the capillary corresponding to the melting temperature of 111 bp (exon 1) and 110 bp (exon 2) low melting domains. The separation was achieved between wild type and mutant sequences as homoduplexes in 15 out of 19 cases, as a single base substitution alters the electrophoretic mobility of a partially melted double stranded fragment. The denaturation and reannealing of wild type and mutant fragments together created wild type/mutant heteroduplexes. All the heteroduplexes were well resolved from wild type homoduplex. In the current form mutant sequences were detected at a frequency of 10(-3) in the presence of wild type. This study has resulted in obtaining electrophoretic spectrum of different N-ras mutants on CDCE as homoduplexes as well as heteroduplexes.
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